Journal of the Korean Society of Mineral and Energy Resources Engineers ISSN:2288-0291(Print) 2288-2790(Online) 한국자원공학회지

Bui, M., Adjiman, C.S., Bardow, A., Fennell, P.S., Fuss, S., Galindo, A., Hackett, L.A., Hallett, J.P., Herzog, H.J., Jackson, G., Kemper, J., Krevor, S., Maitland, G.C., Matuszewski, M., Metcalfe, I.S., Petit, C., Puxty, G., Reimer, J., Reiner, D.M., Rubin, E.S., Scott, S.A., Shah, N., Smit, B., Trusler, J.P.M., Webley, P., Wilcox, J., and Mac Dowell, N., 2021. Carbon capture and storage (CCS): Status and challenges, Energy & Environmental Science, 14, p.2061-2100.

Chen, C.-C. and Evans, L.B., 1986. A local composition model for electrolyte systems, AIChE Journal, 32, p.444-454.

Intergovernmental Panel on Climate Change (IPCC), 2023. AR6 Synthesis Report: Climate Change 2023, IPCC Report, Geneva, Switzerland.

International Energy Agency (IEA), 2020. CCUS in Clean Energy Transitions, Energy Technology Perspectives 2020 Special Report on Carbon Capture Utilisation and Storage, Paris, France, p.13.

Kenig, E.Y., 2018. Rate-based modeling of reactive absorption processes, Chemical Engineering & Technology, 41, p.1915-1928.

Kwak, N.-S., Jung, J., Lee, J., Han, S.-C., Shim, J.-G., Kim, K.-M., and Lee, D.C., 2024. Field demonstration of a 10 MW CO₂ capture pilot plant in extended operation using KoSol absorbents for treating off-gas in a coal-fired power plant, International Journal of Greenhouse Gas Control, 135, 104134.

Kwak, N.-S., Lee, J.H., Lee, I.Y., Jang, K.R., and Shim, J.-G., 2014. A study of new absorbent for post-combustion CO₂ capture test bed, Journal of the Taiwan Institute of Chemical Engineers, 45, p.2549-2556.

Lee, J.H., Kim, B.-J., Shin, S.H., Kwak, N.-S., Lee, D.W., Lee, J.H., and Shim, J.-G., 2016. 0.1 MW test bed CO₂ capture studies with new absorbent (KoSol-5), Applied Chemical Engineering, 27(4), p.391-396.

Lee, J.H., Kim, J.-H., Lee, I.Y., Jang, K.R., and Shim, J.-G., 2011. Performance and economic analysis of 500 MWe coal-fired power plant with post-combustion CO₂ capture process, Korean Chemical Engineering Research, 49(2), p.244-249.

Lee, J.-H., Kwak, N.-S., Lee, I.-Y., Jang, K.-R., and Shim, J.-G., 2012. Performance and economic analysis of domestic supercritical coal-fired power plant with post-combustion CO₂ capture process, Korean Chemical Engineering Research, 50(2), p.365-370.

Lee, J.H., Kwak, N.S., Lee, I.Y., Jang, K.R., Lee, D.W., Jang, S.G., Kim, B.K., and Shim, J.-G., 2015. Performance and economic analysis of commercial-scale coal-fired power plant with post-combustion CO₂ capture, Korean Journal of Chemical Engineering, 32(5), p.800-807.

Lee, J.H., Kwak, N.S., Niu, H., Wang, J., Wang, S., Shang, H., and Gao, S., 2020. KEPCO–China Huaneng post-combustion CO₂ capture pilot test and cost evaluation, Korean Chemical Engineering Research, 58(1), p.150-162.

Que, H. and Chen, C.-C., 2020. Thermodynamic modeling of CO₂ absorption into aqueous amine solutions, Industrial & Engineering Chemistry Research, 59, p.16224-16237.

Rochelle, G.T. and Freeman, S.A., 2018. Thermal energy requirements for CO₂ capture with aqueous amines, Energy Procedia, 114, p.2017-2026.

Shim, J.-G., Kim, J.-H., Lee, J.H., and Jang, K.-R., 2009. Highly efficient absorbents for post-combustion CO₂ capture, Energy Procedia, p.779-782.

United Nations Framework Convention on Climate Change (UNFCCC), 2023. Global Stocktake – Synthesis Report, UNFCCC Report, Bonn, Germany.

Vinjarapu S.H.B., Neerup R., Larsen A.H., Jørsboe J.K., Villadsen S. N. B., Jensen S., Karlsson J.L., Kappel J., Lassen H., Blinksbjerg P., Solms N.V., and Fosbøl P.L., 2024. Results from pilot-scale CO₂ capture testing using 30 wt% MEA at a Waste-to-Energy facility: Optimisation through parametric analysis, Applied Energy, 355, 122193.